RU2558706C1 - Climatic screened camera - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: climatic screened chamber comprises the screened housing, the screened door, the screened input unit with electric connectors, the sealing screening gaskets and air sealing gaskets, low-frequency filters, the device for control of climatic effects inside the test space. The external walls of the screened housing are coated with the radio absorbing material, into the screened housing the test container is inserted which is implemented in the form of TEM-cell the lower wall of which is implemented as a test table, in the walls of the screened housing the electric sensors, heat exchanger tubes, the screening layer from tapes of magnetically soft alloys are embedded. Just near the chamber the temperature and electromagnetic field sensor is located. The screened door is made demountable, its inner side is implemented in the form of test table, and into its internal cavity the electromechanical lock, heat exchanger tubes screening a layer from magnetosoft alloys, and also the screened input unit with protective covers and noise-suppressing filters are inserted, in the cut slot of the screened door the sealing screening, air and sealing gaskets are provisioned, which when closing a door are pressed to the screening groove placed in the screened housing, the door is opened and closed by means of the worm elevator and above the named electromechanical lock the pressing force of which is monitored by above-mentioned electric sensors.

EFFECT: improvement of efficiency of screening of the test container from external electromagnetic radiation and climatic effects.

5 dwg

Description

The invention relates to electrical engineering and can be used to test objects for electromagnetic compatibility with simultaneous electromagnetic and climatic effects on the test object, as well as to measure electromagnetic and thermal emissions under controlled environmental conditions inside and outside the test container.

When designing electronic equipment (RES) it is necessary to take into account the requirements of electromagnetic compatibility, as well as the operability of the device in conditions close to the conditions of actual operation. Under difficult climatic and electromagnetic conditions, the correct operation of the device depends both on the parameters and location of individual components, printed circuit boards, nodes and blocks, and on the parameters and location of their connections. Accordingly, it is necessary at the design stage to take into account the operation of both individual components and the device as a whole in difficult climatic and electromagnetic environments. To solve such problems, simulation and testing are used in a wide range of parameters. The result of the simulation is a model with optimal parameters, for example, a shielded, thermostatic housing and / or chassis with tight connections, into which an integrated system of shielded blocks, nodes and / or printed circuit boards is integrated. The system is placed in an optimal electromagnetic environment and a temperature gradient. The result of this optimization is a housing and / or chassis, characterized by increased resistance to electromagnetic and climatic influences, as well as permissible electromagnetic and thermal emissions. Tests of such devices are carried out using climatic and anechoic chambers. However, when conducting a test in a climate chamber, the test object is not protected from an external electromagnetic field, so that as a result, the actual parameters of the test object may differ from those required in a complex electromagnetic environment. In anechoic chambers, on the contrary, there is control of the electromagnetic field, but there is no possibility of climatic effect on the test object, which, when the device is operated in difficult climatic conditions of the environment, can turn out to be critical and actual parameters may differ from the set ones. These tests must be carried out jointly in order to bring the testing conditions of the device closer to the more real operating conditions.

From patent US 2013/0147650 A1, H01Q 17/00, 06/13/2013 an anechoic chamber is known for studying and testing test objects, including radio-frequency (RF) and microwave (microwave) devices for electromagnetic compatibility. The camera is made as part of a closed hemisphere and contains external side and upper walls in the form of a hemisphere, a round flat wall is located below. The hemisphere inside is covered with an RF absorber. The lower wall is divided into two semicircles, one half is a reflective plane, has no radar absorbing material and forms a semi-anechoic chamber, and the other half is covered with radar absorbent material and forms a completely anechoic chamber. Pyramidal-shaped radar absorbing material was used, the vertices of which are directed to the test object, due to the spherical shape of the walls. The test table is located in the center of the lower flat wall and has a rotation mechanism.

The disadvantages of this camera include the high cost, size and inability to conduct tests under specified climatic conditions, bringing the tests closer to the actual operating conditions of the test object, as well as the difficulties encountered when testing the components, printed circuit boards and electronic components separately.

From patent EP 1283990 B1, G01R 29/08, 02/19/2003 a device for testing the test object for electromagnetic compatibility, a TEM or GTEM camera (transverse electromagnetic wave transmission chamber) is known. The device is designed to measure emissions and test the stability of the test object for electromagnetic compatibility and contains at least six faces of a conductive material with a hole in one of them. Each of the faces is placed in a specific place in space, forming a closed box with an inlet. The internal volume includes a set of conductors, at least one of which is connected to two connectors and is located in a plane whose points are perpendicular to the plane of the test object. The internal volume may also contain elements for mixing electromagnetic radiation, and the conductive structures inside may be coated with radar absorbing material.

The disadvantage of this camera is poor shielding from external electromagnetic radiation, as well as the inability to test the test object with simultaneous climatic and electromagnetic influences.

From the patent EP 1418438 A2, G01R 31/28, 05/12/2004, a climatic chamber is known for conducting research and testing under the influence of heat, cold and moisture on a test object located inside the working volume of the chamber (test container). The climate chamber is made of an airtight container, inside of which there is a test container, a cooling device can be located in these containers. The air drying device is located outside the sealed container, connected to the test container by an air line, contains a desiccant and a heat exchanger of the refrigeration machine. The cooling device contains at least one Peltier element. In a sealed chamber, a temperature of 10-100 C ° is maintained, air humidity in the range of 50-99%. The test container contains humidity and temperature sensors. By heating and supplying dry air to the test container, the test object is dried.

The disadvantage of such a chamber when tested for electromagnetic compatibility is poor shielding from an external electromagnetic field. Accordingly, it is inappropriate to use this camera in research and testing in the microwave range.

Closest to the claimed device is a climate chamber WO 2006/045306 A1, H05K 9/00, G01R 1/04, 31/28, 05/04/2006, designed to test the test object for electromagnetic compatibility. The climate chamber consists of a rectangular shielded enclosure with a cutout for a shielded electrical input module and at least one sealed door. The shielded input module contains low-pass filters and electrical connectors, including coaxial. As sealing gaskets, air and shielding gaskets made of soft conductive foil with high adhesion were used. The camera also includes a climate control unit inside a shielded enclosure.

The disadvantage of the prototype device is that the electromagnetic field is created by a separate emitter located inside the working volume of the camera, so this type of measurement cannot be considered correct. The camera has a low upper frequency of effective shielding, which indicates the impossibility of protection from the external radiation of the test object in a wide range of gigahertz range. Also in this type of cameras there is no way to control air humidity, which for most standards on electromagnetic compatibility is essential.

The inventive climate shielded chamber, including a shielded case, a shielded door, a shielded input module with electrical connectors, shielding gaskets and airtight gaskets, low-pass filters, a device for controlling climatic influences inside the test space, is characterized in that the outer walls of the shielded case are coated with radar absorbing material , a test loop made in the form of a TEM cell is introduced into the shielded case ner, the bottom wall of which is made in the form of a test table, miniature through holes are made in the corner joints of the test container, electric sensors, heat exchanger tubes, a shielding layer of soft magnetic alloy tapes are embedded in the walls of the shielded case, the elements of the device for controlling climatic influences inside the test space are made modular and located on the outer surface of the test container and table, a control circuit with an interface for personal the puter is located in the external control unit, the power electronics circuitry is located in the external radiator unit, the electronic control panel with a liquid crystal screen is mounted on a semi-rigid metal flexible hose near the aforementioned camera, in the immediate vicinity of the camera there is a temperature and electromagnetic field sensor, the shielded door is removable, it the inner side is made in the form of a test table, and an electromechanical lock is introduced into its internal cavity, the tubes are warm exchanger, a shielding layer of soft magnetic alloys, as well as a shielded input module with protective covers and noise filters, in the slot of the shielded door there are sealing shielding, air and sealing gaskets, which when closing the door are pressed against the shielding groove placed in the shielded case, opening and closing the door is made using a worm hoist and the above-mentioned electromechanical lock, the pressing force of which is monitored by the aforementioned mi sensors.

The advantage of the claimed climate chamber, in contrast to the prototype device, is the ability to conduct tests with simultaneous and controlled electromagnetic and climatic (including air humidity) effects on the test object, as well as measuring electromagnetic and thermal emissions from the test object located inside the test container with increased shielding efficiency from an external electromagnetic field.

The technical result to which the proposed climatic shielded chamber is aimed is to conduct research and testing of an object, which is a separate component or a small device as a whole, on electromagnetic compatibility with the simultaneous controlled influence of climatic environmental conditions, in particular, tests on the object's resistance to joint the effects of controlled electromagnetic and temperature fields inside the test container, as well as thermal measurements emissions under electromagnetic influence or measuring thermal and electromagnetic emissions from the test object located at a given value of air humidity inside the test container of the chamber.

The technical result is achieved due to the increased efficiency of the shielding of the test container from external electromagnetic radiation and climatic conditions through the use of radar absorbing material and a multilayer screen of conductive, dielectric and soft materials, as well as by monitoring the external operating conditions of the camera using an external sensor, which includes sensors of electromagnetic field and temperature. Tracking and maintaining the temperature field and humidity inside the test container, made in the form of a TEM cell, is carried out using a climate system consisting of two subsystems (internal and external), which ensures a uniform temperature field and air humidity in the test container. The elements of the climate system are located outside the test container, which reduces the uncontrolled re-reflection of electromagnetic radiation inside the test container. The external subsystem is made in the form of modules that are located and evenly distributed between the inner surface of the shielding housing and the outer surface of the test container. The internal subsystem provides a given circulation, temperature and humidity of the air flow passing through the air lines through the test container, in which miniature openings are made. The test object is loaded using a removable door with an electromechanical lock and a lift with an input with electrical connectors.

The invention is illustrated by drawings, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only illustrative materials of a particular case of execution:

Figure 1 shows an isometric view of a climatic shielded camera.

Figure 2 shows a diagram of a device for controlling climatic influences inside a test container.

Figure 3 shows a rear view and a left view of the climate shielded camera.

Figure 4 shows an isometric view of a removable door.

5 is a front view of an electrical input module.

The climate shielded chamber consists of a shielding housing 1, a radiator unit 2, a control panel 3 with a flexible shielding hose 4, a shielding skirt 5, a removable door 6 on the worm hoist 7, protective support posts 8, an external temperature and electromagnetic field sensor 9 and a control system unit climatic influences inside the test container 10.

The climate control system includes an internal 36 and an external 31 subsystem under the control of a microprocessor (MP) 27 with software implementation proportional to the integral differential (PID) controller, a control panel (PU) 3 with a liquid crystal display (LCD), a power supply unit 32, a standalone power supply 33, drivers with stepper motors 34 for worm hoists 7 of door 6, as well as an interface for connecting an external personal computer 30. External 31 subsystem consists of modules that located in cells 19 between the outer surface of the test container 13 and the surface of the inner shell of the shielding housing 12. The module contains a Peltier element, a flat heating element (PEN), temperature and electromagnetic field sensors, the information from which comes directly to MP 27, and the elements are controlled by MP through the power electronic module 26. The cooling of the modules is carried out by means of active 22 and passive 24 cooling systems. Active 22 cooling system contains a refrigeration machine, a heat exchanger (evaporator) 17 of which is located in the cavity 21 of the shielding housing, and the passive 24 system is made by a closed loop of hollow metal tubes 28 in which the air flow is circulated by a fan, thereby ensuring the necessary operating temperature of the modules, as well as the set temperature of the shielding housing. The internal 36 climate control subsystem contains the air line of the incoming 15 and 18 outgoing air flows from the test container with air electric valves 23, an evaporator, a steam generator, an accumulator with Peltier and PEN elements, a temperature, humidity and air pressure sensor, a recirculation fan and a compressor for circulation air mixture through a test container.

The shielding case is made in the form of a rectangular parallelepiped with a two-layer shell made of metal sheet material with high thermal conductivity (at least 200 W / m × K) and electrical conductivity (at least σ = 37 × 10 ⁶ S / m), and contains an outer shell 11 , on the outer surface of which there is a radar absorbing material 25, and the inner shell 12. In the cavity 21 between the inner 12 and the outer 11 shells are a shielding layer of tapes of soft magnetic alloys 14, a heat-insulating layer 16, a heat exchanger (evaporator) Shnei active climate system 17, brakes manifold internal air conditioner system 15, the incoming and outgoing air streams 18 of the test container. Test container 13 is made in the form of a TEM cell of a metal material with high electrical and thermal conductivities.

The radiator unit 2 is made of a metal material with high thermal conductivity (at least 200 W / m × K), has closed cooling fins 37, through which the air flow circulates through one or more fans 38, and the radiator unit has shielded cavities for placement of electric connections 39, elements of power electronics 40, internal and external subsystems of the climate control system 41. Between the above-mentioned radiator unit and the shielding case there are connections in the form of hollow taping pipes of conductive material, in which there are electrical connections 44, air lines 42 and pipes of the heat exchanger 43 of the internal and external subsystems of the climate control system, and also provide structural rigidity as a whole.

External sensor 9 of temperature and electromagnetic field is made in the form of a separate device and contains a digital temperature and electromagnetic field sensor. The electromagnetic field sensor is made of antennas E and H of the field component, the signal from each of which is fed through its input circuit to its own logarithmic amplifier, which is then digitized by the controller. A signal from a digital temperature sensor is also suitable for the controller. Information about the temperature and electromagnetic field from the controller is fed to the fiber-optic communication converter, and information is transmitted to the climate control unit, in particular to MP 27.

The removable door 6 is located on the worm hoists 7, which can be completely manually unscrewed, while the door can be completely removed if necessary. The door is made of metallic conductive material with high thermal and electrical conductivity. The inner 48 and outer 53 of the door wall, when closed, form the shell of a closed rectangular parallelepiped of the shielding case. On the outer side of the outer wall is a radar absorbing material 25 and connectors of the electrical input 29 for instrumentation. In the cavity between the inner and outer walls there are materials similar to those used in the shielding case, as well as part of the contour of the external passive 28 cooling system made of metal hollow tubes through which the air flow circulates, and interference protection filters of the electrical input 35, which have electrical connectors inside 45 of the test container 13, located on the test table 46 for connection with the test object 20, and electrical connectors on the outside 57, located on the protective cover 56 for connecting instrumentation. Between the test table 46, on which the test object 20 is placed, and the outer side of the inner wall of the door 48 are the modules of the external climate control subsystem. Shielding 49 and sealing 50 gaskets are soldered around the perimeter of the test table. The rigidity of the door structure is ensured by the base 52, which is a frame of metallic conductive material with a triangular cross section. Along the perimeter of the frame there are slots for shielding and sealing 54 gaskets and inserts, as well as hollow cylindrical protrusions for screw lock rods 55. At the corners of the frame base there are bushings made in the form of a pyramid with a threaded hole for worm hoists 47.

Claims (1)

A climate shielded chamber, including a shielded enclosure, a shielded door, a shielded input module with electrical connectors, shielding gaskets and airtight gaskets, low-pass filters, a device for controlling climatic influences inside the test space, characterized in that the outer walls of the shielded enclosure are coated with radar absorbing material, a test container made in the form of a TEM cell is introduced into the shielded case, the lower the wall of which is made in the form of a test table, miniature through holes are made in the corner joints of the test container, electric sensors, heat exchanger tubes, a shielding layer of soft magnetic alloy tapes are introduced into the walls of the shielded case, the elements of the device for controlling climatic influences inside the test space are made modular and located on the external surface of the test container and the table, a control circuit with an interface for a personal station laid in the external control unit, the power electronics circuit is located in the external radiator unit, an electronic control panel with a liquid crystal screen is mounted on a semi-rigid metal flexible hose near the aforementioned camera, in the immediate vicinity of the camera there is a temperature and electromagnetic field sensor, the shielded door is removable, its internal the side is made in the form of a test table, and an electromechanical lock, heat exchanger tubes, eq. soft-alloying wound layer, as well as a shielded input module with protective covers and noise filters, in the slot of the shielded door there are sealing shielding, air and sealing gaskets, which, when closing the door, are pressed to the shielding groove located in the shielded case, the door is opened and closed by means of a worm hoist and the aforementioned electromechanical lock, the pressing force of which is monitored by the aforementioned electrical sensors.

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